Selecting μ → e conversion targets to distinguish lepton flavour-changing operators

Davidson, Sacha; Kuno, Y.; Yamanaka, Masato

doi:10.1016/j.physletb.2019.01.042

Cited by 39 publications

(76 citation statements)

References 42 publications

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“…Appendix C: Q 2 dependence of meson propagators and form factors Let us note that in Eqs. (9), (10), (16), (22), and (23), we neglected the squared momentum transfer Q 2 -dependence of the meson propagator and the form factorsg M 1 2 (Q 2 ). For most of the processes of our current interest, this Q 2dependence results in a less than 5% deviation from the approximate formulae that we use, which for our purposes is more than sufficient.…”

Section: Discussionmentioning

confidence: 99%

“…From Eqs. (15), (16), (22) and (23), we deduce upper limits for the branching ratios of the two-body LFV decays M (Z) → 1 2 of neutral vector and pseudoscalar mesons and Z-boson, using the existing data (1)-(3) for three-body LFV decays τ (µ) → 3 . We present our results in the second column of Table I and compare them with the limits derived from the study of lepton conversion [2] and available experimental data [1].…”

Section: Limits On Two-body Lfv Meson Decaysmentioning

confidence: 99%

“…(7), and the meson-lepton couplings, g M , from (8), which are shown in Appendix D. Using these relations in the decay rate formulas for Γ(M → l 1 l 2 ) from Appendix A and substituting them into Eqs. (15), (16), (22) and (23), we set upper limits on the coefficients C/Λ 2 of the effective operators (7) from the experimental data on τ (µ) → 3 . There are several operators contributing simultaneously to each of these processes, and therefore the data impose upper limits on linear combinations of the corresponding Wilson coefficients shown in Appendix E. In practice, it is useful to have individual upper limits for these coefficients under certain reasonable assumptions.…”

Section: Quark-lepton Effective Operators In Lfv Decays Of µ τmentioning

confidence: 99%

“…[3]- [9] and further used in a series of papers (see, e.g., Refs. [10]- [22]). In particular, in Refs.…”

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Bounds on lepton flavor violating physics and decays of neutral mesons from τ(μ)→3ℓ , ℓγγ
Dib
¹
,
Gutsche
²
,
Kovalenko
³

et al. 2019
Phys. Rev. D
9
0
16
0
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We study two-and three-body lepton flavor violating (LFV) decays involving leptons and neutral vector bosons V = ρ 0 , ω, φ, J/ψ, Υ, Z 0 , as well as pseudoscalar P = π 0 , η, η , ηc and scalar S = f0(500), f0(980), a0(980), χc0(1P ) mesons, without referring to a specific mechanism of LFV realization. In particular, we relate the rates of the three-body LFV decays τ (µ) → 3 , where = µ or e, to the two-body LFV decays (V, P ) → τ µ(τ e, µe), where V and P play the role of intermediate resonances in the decay process τ (µ) → 3 . From the experimental upper bounds for the branching ratios of τ (µ) → 3 decays, we derive upper limits for the branching ratios of (V, P ) → τ µ(τ e, µe). We compare our results to the available experimental data and known theoretical upper limits from previous studies of LFV processes and find that some of our limits are several orders of magnitude more stringent. Using the idea of quark-hadron duality, we extract limits on various quark-lepton dimension-six LFV operators from data on lepton decays. Some of these limits are either new or stronger than those existing in the literature.

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Section: Discussionmentioning

confidence: 99%

Section: Limits On Two-body Lfv Meson Decaysmentioning

confidence: 99%

Section: Quark-lepton Effective Operators In Lfv Decays Of µ τmentioning

confidence: 99%

“…[3]- [9] and further used in a series of papers (see, e.g., Refs. [10]- [22]). In particular, in Refs.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Bounds on lepton flavor violating physics and decays of neutral mesons from τ(μ)→3ℓ , ℓγγ
Dib
¹
,
Gutsche
²
,
Kovalenko
³

et al. 2019
Phys. Rev. D
9
0
16
0
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show abstract

“…We remark that in parallel to model specific studies there has been significant recent progress on model-independent effective field theoretical (EFT) approaches to CLFV: loop corrections to µ → eγ have been evaluated in an EFT with dimension-6 operators [39,40]; higher-order corrections to µ → eγ, µ → eee and µ → e from running below the weak scale have been evaluated [41][42][43] and disentanglement of different Wilson coefficients by experimental observables has been studied [44,45].…”

Section: Jhep08(2019)082mentioning

confidence: 99%

Low-energy lepton physics in the MRSSM: (g − 2)μ, μ→eγ and μ→e conversion

Stöckinger

Stöckinger-Kim

2019

J. High Energ. Phys.

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Low-energy lepton observables are discussed in the Minimal R-symmetric Supersymmetric Standard Model. We present comprehensive numerical analyses and the analytic one-loop results for (g − 2) µ , µ → eγ, and µ → e conversion. The interplay between the three observables is investigated as well as the parameter regions with large g − 2. A striking difference to the MSSM is the absence of tan β enhancements; however we find smaller enhancements governed by MRSSM-specific R-Higgsino couplings λ d and Λ d. As a result we find significant contributions to g − 2 only in a small parameter space with several SUSY masses below 200 GeV, compressed spectra and large λ d , Λ d. In this parameter space there is a correlation between all three considered observables. In the parameter region with small (g − 2) µ the SUSY masses can be larger and the correlation between µ → eγ and µ → e conversion is weak. Therefore already COMET Phase 1 has a promising sensitivity to the MRSSM.

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Completeness and complementarity for μ → eγ, μ → $$ e\overline{e}e $$ and μA → eA

Davidson

2021

J. High Energ. Phys.

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Lepton Flavour Violation (LFV) is New Physics that must occur, but is stringently constrained by experiments searching for μ ↔ e flavour change, such as μ → eγ, μ →$$ e\overline{e}e $$ e e ¯ e or μ → e conversion. However, in an Effective Field Theory(EFT) parametrisation, there are many more μ ↔ e operators than restrictive constraints, so determining operator coefficients from data is a remote dream. It is nonetheless interesting to learn about New Physics from data, so this manuscript introduces “observable-vectors” in the space of operator coefficients, which identify at any scale the combination of coefficients probed by the observable. These vectors have an overlap ≳ 10−3 with most of the coefficients, and are used to study whether μ → eγ, μ →$$ e\overline{e}e $$ e e ¯ e and μ → e conversion give complementary information about New Physics. The appendix gives updated sensitivities of these processes, (and a subset of τ → ℓ decays), to operator coefficients at the weak scale in the SMEFT and in the EFT below mW.

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Selecting μ → e conversion targets to distinguish lepton flavour-changing operators

Cited by 39 publications

References 42 publications

Bounds on lepton flavor violating physics and decays of neutral mesons from τ(μ)→3ℓ , ℓγγ
Dib
¹
,
Gutsche
²
,
Kovalenko
³

et al. 2019
Phys. Rev. D
9
0
16
0
View full text Add to dashboard Cite

Bounds on lepton flavor violating physics and decays of neutral mesons from τ(μ)→3ℓ , ℓγγ
Dib
¹
,
Gutsche
²
,
Kovalenko
³

et al. 2019
Phys. Rev. D
9
0
16
0
View full text Add to dashboard Cite

Low-energy lepton physics in the MRSSM: (g − 2)μ, μ→eγ and μ→e conversion

Completeness and complementarity for μ → eγ, μ → $$ e\overline{e}e $$ and μA → eA

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Selecting μ → e conversion targets to distinguish lepton flavour-changing operators

Cited by 39 publications

References 42 publications

Bounds on lepton flavor violating physics and decays of neutral mesons from τ(μ)→3ℓ , ℓγγDib1, Gutsche2, Kovalenko3 et al. 2019Phys. Rev. D90160View full textAdd to dashboardCite

Bounds on lepton flavor violating physics and decays of neutral mesons from τ(μ)→3ℓ , ℓγγDib1, Gutsche2, Kovalenko3 et al. 2019Phys. Rev. D90160View full textAdd to dashboardCite

Low-energy lepton physics in the MRSSM: (g − 2)μ, μ→eγ and μ→e conversion

Completeness and complementarity for μ → eγ, μ → $$ e\overline{e}e $$ and μA → eA

Contact Info

Product

Resources

About

Selecting μ → e conversion targets to distinguish lepton flavour-changing operators

Bounds on lepton flavor violating physics and decays of neutral mesons from τ(μ)→3ℓ , ℓγγ
Dib
¹
,
Gutsche
²
,
Kovalenko
³

et al. 2019
Phys. Rev. D
9
0
16
0
View full text Add to dashboard Cite

Bounds on lepton flavor violating physics and decays of neutral mesons from τ(μ)→3ℓ , ℓγγ
Dib
¹
,
Gutsche
²
,
Kovalenko
³

et al. 2019
Phys. Rev. D
9
0
16
0
View full text Add to dashboard Cite